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有限理性视野下网络交通流逐日演化规律研究

李涛 关宏志 梁科科

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有限理性视野下网络交通流逐日演化规律研究

李涛, 关宏志, 梁科科

Day-to-Day dynamical evolution of network traffic flow under bounded rational view

Li Tao, Guan Hong-Zhi, Liang Ke-Ke
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  • 基于有限理性的前提假设,建立了有限理性二项logit模型,用以描述出行者路径选择行为,并以一个由2条路径构成的路网为例,探讨了理性程度不同群体的网络交通流逐日动态演化过程. 通过数值实验,分析了网络交通流的演化特征,发现网络交通流演化最终状态除了与出行者群体对费用的敏感程度、对实际费用的依赖程度有关,还与出行者群体的理性程度有很大关系. 在一定的情况下,出行者理性程度很高或很低均可以使系统稳定,而恰恰是理性程度一般的群体不容易达到稳定.
    The formation mechanism of network traffic flow and its evolution law are closely related to daily activities of travelers. The current studies indicate that the law of network traffic flow evolution is day-to-day; therefore, using days as the scale unit is an important way to illustrate the evolution of network traffic flow. In previous studies, travelers in the network were tacitly assumed to be entirely rational. When the rationality of travelers is limited, the dynamics of the evolution law needs to be re-examined. This paper presents the utility maximization hypothesis in a logit model by using the bounded rationality hypothesis and develops a bounded rational binary logit (BRBL) model. We apply the BRBL model to a day-to-day network traffic flow distribution and discuss the evolution law of day-to-day network traffic flow under the assumption of the limited rationality of travelers. Through a numerical experiment, this paper analyzes the evolution characteristics of network traffic flow. The results are as follows. Firstly, the final state of the network traffic flow process is not only correlated to the cost-sensitivity of travelers and dependence on actual cost, but also strongly related to the degree of the nationality of travelers. Secondly, the system will be either bifurcated or chaotic when either cost-sensitivity increases or dependence on actual cost increases. Moreover, within the group of travelers whose rationality level is low, no matter what the cost-sensitivity of travelers and the dependence on actual cost are, the evolution results are asymptotically stable. Finally, in particular, in certain circumstances, it is easy to achieve stability when the rationallty degree of travelers is very high or very low, while it is not easy to achieve stability when the rationality degree of travelers is medium.
      通信作者: 李涛, jiaowo87@emails.bjut.edu.cn
    • 基金项目: 国家重点基础研究发展计划(批准号:2012CB725403)、国家自然科学基金重点项目(批准号:51338008)、国家自然科学基金面上项目(批准号:51378036)和国家自然科学基金青年基金项目(批准号:51308018)资助的课题.
      Corresponding author: Li Tao, jiaowo87@emails.bjut.edu.cn
    • Funds: Project supported by the National Basic Research Program of China (Grant No. 2012CB725403), the National Natural Science Foundation of China (Grant No. 51338008), the National Natural Science Foundation of China (Grant No. 51378036) and the National Natural Science Foundation of China (Grant No. 51308018).
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    Watling D, Hazelton M L 2003 Netw. Spat. Econ. 3 349

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    Bie J, Lo H K 2010 Transp. Res. B 44 90

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    Mahmassani H S, Jou R C {2000 Transp. Res. Part A 34 243

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    Lou Y, Yin Y, Lawphongpanich S 2010 Transp. Res. Part B 44 15

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    Avineri E, Prashker J N 2003 Transp. Res. Record 1854 90

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    Avineri E 2004 J. Intellig. Transp. Syst. 8 195

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    Avineri E, Prashker J N {2005 Transp. Res. Part C 13157

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  • [1]

    Liu S X, Guan H Z, Yan H 2012 Acta Phys. Sin. 61 090506 (in Chinese) [刘诗序, 关宏志, 严海 2012 物理学报 61 090506]

    [2]

    Cascetta E, Cantarella G E {1991 Transp. Res. B 18 13

    [3]

    Cantarella G E, Cascetta E 1995 Transp. Sci. 29 305

    [4]

    Nakayama S, Kitamura R, Fujii S 1999 Trans. Res. Rec. 1676 30

    [5]

    Nakayama S, Kitamura R 2000 Transp. Res. Rec. 1725 63

    [6]

    Nakayama S, Kitamura R, Fujii S 2001 Transp. Res. Rec. 1752 62

    [7]

    Klgl F, Bazzan A L C 2002 Proc. of the First Int. Joing Conf. on Autonomous Agents and Multi-angent Systems Bologna, Italy, July 15-19, 2002 p217

    [8]

    Klgl F, Bazzan A L C {2004 J. Artific. Soc. Soc. Simulat. 7 1

    [9]

    Klgl F, Bazzan A L C 2004 J. Intellig. Transp. Syst. 8 223

    [10]

    Liu T L, Huang H J {2005 Intellig. Transp. Syst. 4 17 (in Chinese) [刘天亮, 黄海军 2005 通讯 4 17]

    [11]

    Liu T L, Huang H J 2007 Acta Phys. Sin. 56 6321 (in Chinese) [刘天亮, 黄海军 2007 物理学报 56 6321]

    [12]

    Kim H, Oh J S, Jayakrishnan R 2009 KSCE J. Civil Engineer. 13 117

    [13]

    Smith M J 1984 Transp. Sci. 18 245

    [14]

    Friesz T L, Bemstein D, Mehta N J, Tobin R L, Ganjalizadeh S 1994 Oper. Res. 42 1120

    [15]

    Zhang D, Nagumey A 1996 Transp. Res. B 30 245

    [16]

    Nagumey A, Zhang D 1997 Transp. Sci. 31 147

    [17]

    Watling D 1999 Transp. Res. B 33 281

    [18]

    Cho H J, Hwang M C 2005 Math. Comput. Model. 41 501

    [19]

    Mounce R 2006 Transp. Res. B 40 779

    [20]

    Guo R Y, Huang H J {2008 J. Managem. Sci. China 11 12 (in Chinese) [郭仁拥, 黄海军 2008 管理科学学报 11 12]

    [21]

    Horowitz J L {1984 Transp. Res. B 18 13

    [22]

    Cascetta E, Cantarella G E 1991 Transp. Res. A 25 277

    [23]

    Cantarella G E, Cascetta E 1995 Transp. Sci. 29 305

    [24]

    Watling D, Hazelton M L 2003 Netw. Spat. Econ. 3 349

    [25]

    Bie J, Lo H K 2010 Transp. Res. B 44 90

    [26]

    Nakayama S 2004 The 83rd Annual Meeting of the Transportation Research Board Washington, D.C., January 11-15, 2004

    [27]

    Simon H A {1995 Quart. J. Economics 69 343

    [28]

    Huang Z W, Zhou J Z, He H, Zhang X Y, Wang C Q {2011 J. Mech. Engineer. 47 59 (in Chinese) [黄志伟, 周建中, 贺徽, 张孝远, 王常青 2011 机械工程学报 47 59]

    [29]

    Wang X Y, Wang M J 2008 Physica A 387 3751

    [30]

    Zhang L S, Cai L, Feng C W 2010 Acta Electron. Sin. 38 1 (in Chinese) [张立森, 蔡理, 冯朝文 2010 电子学报 38 1]

    [31]

    Tang Y, Fang B, Zhang Y W, Li Q F 2011 J. Vib. Shock 30 269 (in Chinese) [唐冶, 方勃, 张业伟, 李庆芬 2011 振动与冲击 30 269]

    [32]

    Ma C, Wang X Y 2012 Commun. Nonlinear Sci. Numer. Simulat. 17 721

    [33]

    Zhang W, Song C Z 2007 Int. J. Bifurcat. Chaos 17 1637

    [34]

    Hu J, Chung K W, Chan C L 2007 Appl. Dyn. Syst. 6 29

    [35]

    Jiang J, Ulbrich H 2005 ASME J. Vib. Acoust. 127 594

    [36]

    Chen L Q 2005 ASME, Appl. Mech. Reviews 58 91

    [37]

    Mahmassani H S, Chang G L 1986 Transp. Res. Part B 20 297

    [38]

    Mahmassani H S, Chang G L 1987 Transp. Sci. 21 89

    [39]

    Mahmassani H S, Jou R C {2000 Transp. Res. Part A 34 243

    [40]

    Lou Y, Yin Y, Lawphongpanich S 2010 Transp. Res. Part B 44 15

    [41]

    Avineri E, Prashker J N 2003 Transp. Res. Record 1854 90

    [42]

    Avineri E 2004 J. Intellig. Transp. Syst. 8 195

    [43]

    Avineri E, Prashker J N {2005 Transp. Res. Part C 13157

    [44]

    Liu Z H 2006 Fundamentals and Applications of Chaotic Dynamic (Beijing: Higher Education Press) pp9-14, 60 (in Chinese) [刘宗华 2006 混沌动力学基础及其应用(北京: 高等教育出版社)第9-14, 60页]

    [45]

    Di X, Liu H X, Pang J S, Ban X G 2013 Transp. Res. Part B 57 300

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出版历程
  • 收稿日期:  2016-03-11
  • 修回日期:  2016-05-31
  • 刊出日期:  2016-08-05

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